HAL 0.5.10 Specification

This document concerns the specification of HAL which is a piece of software that provides a view of the various hardware attached to a system. In addition to this, HAL keeps detailed metadata for each piece of hardware and provide hooks such that system- and desktop-level software can react to changes in the hardware configuration in order to maintain system policy.

HAL represents a piece of hardware as a device object. A device object is identified by a unique identifer and carries a set of key/value paris referred to as device properties. Some properties are derived from the actual hardware, some are merged from device information files and some are related to the actual device configuration. This document specifies the set of device properties and gives them well-defined meaning. This enable system and desktop level components to distinguish between the different device objects and discover and configure devices based on these properties.

HAL provides an easy-to-use API through D-Bus which is an IPC framework that, among other things, provides a system-wide message-bus that allows applications to talk to one another. Specifically, D-Bus provides asynchronous notification such that HAL can notify other peers on the message-bus when devices are added and removed as well as when properties on a device are changing.

The most important goal of HAL is to provide plug-and-play facilities for UNIX-like desktops with focus on providing a rich and extensible description of device characteristics and features. HAL has no other major dependencies apart from D-Bus which, given sufficient infrastructure, allows it to be implemented on many UNIX-like systems. The major focus, initially, is systems running the Linux 2.6 series kernels.

Acknowledgements

Havoc Pennington's article ''Making Hardware Just Work'' motivated this work. The specification and software would not exist without all the useful ideas, suggestions, comments and patches from the Free Desktop and HAL mailing lists.

All trademarks mentioned belong to their respective owners.

Architecture of HAL

The HAL consists of a number of components as outlined in the diagram below. Note that this diagram is high-level and doesn't capture all implementation details.

Details on each component

HAL daemon
A system-wide service that maintains a database of device objects. The daemon is responsible for merging information from device information files and managing the life cycle of device objects. The service is implemented as a daemon and uses helpers to query devices for specific information.
Applications
These are applications consuming services from HAL; this includes desktop-wide session daemons for maintaining policy such as power and disk/volume management.
Callouts
Callouts are programs that run when device objects are added and removed in the HAL daemon. This is useful for 3rd party software to merge additional information onto the device object before it is announced on D-Bus. Callouts are specified on a per-device basis with the info.callouts.add and info.callouts.remove. See the section called “ info namespace ” for details.
Methods
It is possible to specify that a given HAL device object implements a specific D-Bus interface, e.g. org.freedesktop.Hal.Device.Frob with a set of methods Foo, Bar and Baz and have programs run when applications call into this interface. This is defined in the info.interfaces property, consult the section called “ info namespace ” for details.
Addons
An addon can be characterized as a daemon whose life cycle is tied to a device object in HAL. And addon can also claim a specific interface on the device object to provide services to applications for configuring / using the device without having to spawn a new program for every method call. HAL provides a facility to launch/destroy one or more addons per device object using the info.addons property. See the section called “ info namespace ” for details.
Device Information Files
A set of files that matches properties on device objects and merges additional information. These files are used, for among other things, to specify what callouts, methods and addons to associate with a device object. For example, for drives using removable media, HAL includes an add-on daemon which sole purpose is to continously poll the drive to detect media change.

The D-Bus system message bus is used to provide a ''network API'' to applications. As D-Bus is designed to be language independent, potentially many languages / runtime systems will be able to easily access the services offered by HAL.

Device Objects

It is important to precisely define the term HAL device object. It's actually a bit blurry to define in general, it includes what most UNIX-like systems consider first class objects when it comes to hardware. In particular, a device object should represent the smallest unit of addressable hardware. This means there can be a one-to-many relationship between a physical device and the device objects exported by HAL. Specifically, a multi-function printer, which appear to users as a single device may show up as several device objects; e.g. one HAL device object for each of the printing, scanning, fax and storage interfaces. Conversely, some devices may be implemented such that the HAL device object represent several functional interfaces. HAL is not concerned with this duality of either one-to-many or many-to-one relationships between device objects and the actual iron constituting what users normally understand as a single piece of hardware; a device object represents the smallest addressable unit.

Device objects in HAL are organised on a by-connection basis, e.g. for a given device object X it is possible to find the device object Y where X is attached to Y. This gives structure to the device database of HAL; it is possible to map the devices out in a tree. Further, software emulation devices exported by the operating system kernel, such as SCSI emulation for USB Storage Devices, are also considered device objects in HAL. This implies that operating system kernel specific bits leak into the device object database. However applications using HAL will not notice this, such device objects are not referenced anywhere in the device objects that users are interested in; they are merely used as glue to build the device tree.

In addition to provide information about what kind of hardware a device object represents (such as a PCI or USB device) and how to address it, HAL merges information about the functional interfaces the operating system kernel provides in order to use the device; in most cases this is represented on the device object as a string property with the name of the special device file in /dev. In addition to the special device file, a number of other useful properties are merged. This means that both hardware and functional properties are on the same device object, which may prove to be useful for an application programmer. For example, an application might query HAL for the device object that exports the special device file /dev/input/mouse2 and learn that this is provide by an USB mouse from a certain manufacturer by checking the properties that export the USB vendor and product identifiers. See the section called “Device Capabilities” and Chapter 5, Device Properties for details.

Finally, HAL provides one or more D-Bus interfaces for applications to configure and/or use the device. These interfaces are discussed in Chapter 6, D-Bus interfaces.

Summarizing, a device object is comprised by

UDI
This is the the Unique Device Identifer, that is unique for a device object - that is, no other device object can have the same UDI at the same time. The UDI is computed using bus-specific information and is meant to be unique across device insertions and independent of the physical port or slot the device may be plugged into.
Properties
Each device object got a set of properties which are key/value pairs. The key is an ASCII string while the value can be one of several types, see below. Properties are arranged into name spaces using ''.'' as a separator.
- string - UTF8 string
- strlist - ordered list with UTF8 strings
- int - 32-bit signed integer
- uint64 - 64-bit unsigned integer
- bool - truth value
- double - IEEE754 double precision floating point number
Interfaces
Applications can configure and/or use a device using D-Bus interfaces. Typically, there's a one-to-one relationship between capabilities/namespaces and interfaces.

Properties of a device object carry all the important information about a device object. For organisational reasons properties are also namespaced using ''.'' as a separator.

It can be useful to classify properties into four groups

Metadata - Information about how the devices are connected with respect to each other (parent/child relationships), what kind of device it is, what functionality it provides etc.
Facts - vendor ID, product ID, disk serial numbers, number of buttons on a mouse, formats accepted by a mp3 player and so on.
Usage specific information - Network link status, special device file name, filesystem mount location etc.
Policy - How the device is to be used be users; usually defined by the system administrator.

The first category is determined by HAL, the second category includes information merged from either querying the hardware itself or from device information files. The third category is intercepted by monitoring the hardware and finally the last is merged from files under control of the system administrator. This document is concerned with precisely defining several properties; see Chapter 5, Device Properties and onwards for more information. As a complement to device properties, HAL also provides conditions on HAL device objects. Conditions are used to relay events that are happening on devices which are not easily expressed in properties. This includes events such as ''processor is overheating'' or ''block device unmounted''.

There is a special hal device object referred to as the ''root computer device object''. This device object represent the entire system as a whole and all other devices are either directly or indirectly childs of this device object. It has the UDI /org/freedesktop/Hal/devices/computer.

The fundamental idea about HAL is that all ''interesting'' information about hardware that a desktop application needs, can be obtained by querying HAL. Below is a screenshot of a simple device manager application shipped with HAL called hal-device-manager. This application is communicating with the HAL daemon and displays the tree of device objects. The shown properties are for a device object representing a harddisk.

Device Capabilities

Mainstream hardware isn't very good at reporting what it really is, it only reports, at best, how to interact with it. This is a problem; many devices, such as MP3 players or digital still cameras, appear to the operating system as plain USB Mass Storage devices when the device in fact is a lot more than just that. The core of the problem is that without external metadata, the operating system and desktop environment will present it to the user as just e.g. a mass storage device.

As HAL is concerned with merging of external metadata, through e.g. device information files, there needs to be some scheme on how to record what the device actually is. This is achieved by two textual properties, info.category and info.capabilities. The former describes what the device is (as a single alphanumeric keyword) and the latter describes what the device does (as a number of alphanumeric keywords separated by whitespace). The keywords available for use is defined in this document; we'll refer to them in following simply as capabilities.

HAL itself, assigns capabilities on device detection time by inspecting the device class (if available, it depends on the bus type) and looking at information from the operating system and the hardware itself.

User mode drivers such as libgphoto2 and sane provides device information to merge information about devices they can drive. As such, device objects represent an USB interface gain additional properties such as ''scanner'' or ''camera''.

Having a capability also means that part of the property namespace, prefixed with the capability name, will be populated with more specific information about the capability. Indeed, some properties may even be required such that applications and device libraries have something to expect. For instance, the capability for being a MP3 player may require properties defining what audio formats the device support (e.g. Ogg and MP3), whether it support recording of audio, and how to interact with the device. For example, the latter may specify ''USB Storage Device'' or ''proprietary protocol, use libfooplayer''.

Finally, capabilities have an inheritance scheme, e.g. if a device has a capability foo.bar, it must also have the capability foo.

Chapter 2. Device Information Files

Table of Contents

Matching
Merging
Search Paths

Device information files (.fdi files is a shorthand) are used to merge arbitrary properties onto device objects. The way device information files works is that once all device properties are merged onto a device object it is tried against the set of installed device information files. Device information files are used for both merging facts and policy settings about devices.

Matching

Each device information file got a number of <match key="some_property" [string|int|bool|..]="required_value" > directives that is tested against the properties of the device object. If all the match directives passes then the device information can include <[merge|append|prepend|addset] key="some_property" type="[string|int|bool|..]"> directives to respectively merge new properties or append to existing properties on the device object. It's important to emphasize that any previously property stemming from device detection can be overridden by a device information file.

The <match>, <merge>, <append>, <prepend> and <addset> directives always requires the key attribute which must be either a property name on the device object in question or a path to a property on another device object. The latter case is expressed either through direct specification of the UDI, such as /org/freedesktop/Hal/devices/computer:foo.bar or indirect references such as @info.parent:baz where the latter means that the device object specified by the UDI in the string property info.parent should be used to query the property baz. It is also possible to use multiple indirections, e.g. for a volume on a USB memory stick the indirection @block.storage_device:@storage.originating_device:usb.vendor_id will reference the usb.vendor_id property on the device object representing the USB interface.

When the property to match have been determined a number of attributes can be used within the <match> tag:

string - match a string property; for example <match key="foo.bar" string="baz"> will match only if 'foo.bar' is a string property assuming the value 'baz'.
int - match an integer property
uint64 - match property with the 64-bit unsigned type
bool - match a boolean property
double - match a property of type double
exists - used as <match key="foo.bar" exists="true">. Can be used with 'true' and 'false' respectively to match when a property exists and it doesn't.
empty - can only be used on string or strlist properties with 'true' and 'false'. The semantics for 'true' is to match only when the string is non-empty.
is_ascii - matches only when a string property contain only ASCII characters. Can be used with 'true' or 'false'.
is_absolute_path - matches only when a string property represents an absolute path (the path doesn't have to exist). Can be used with 'true' or 'false'.
sibling_contains - can only be used with string and strlist (string list). For a string key this matches when a sibling item contains the (sub-)string in the same property. For a string list, this is if a string matches an item in the list.
contains - can only be used with string and strlist (string list). For a string key this matches when the property contains the given (sub-)string. For a string list this match if the given string match a item of the list.
contains_ncase - like contains but the property and the given key are converted to lowercase before check.
contains_not - can only be used with strlist (string list) and string properties. For a string list this match if the given string not match any of the item of the list (or the property is not set for the device). For a string this match of the property not contains the (sub-)string. You can use this attribute to construct if/else blocks together with e.g. contains.
prefix - can only be used with string properties. Matches if property begins with the key.
prefix_ncase - like prefix but the property and the given key are converted to lowercase before the check.
suffix - can only be used with string properties. Matches if property ends with the key.
suffix_ncase - like suffix but the property and the given key are converted to lowercase before the check.
compare_lt - can be used on int, uint64, double and string properties to compare with a constant. Matches when the given property is less than the given constant using the default ordering.
compare_le - like compare_lt but matches when less than or equal.
compare_gt - like compare_lt but matches when greater than.
compare_ge - like compare_lt but matches when greater than or equal.
compare_ne - like compare_lt but matches when not equal.

Merging

The <merge>, <append>, <prepend> and <addset> directives all require the type attribute which specifies what to merge. The following values are supported

string - The value is copied to the property. For example <merge key="foo.bar" type="string">baz</merge> will merge the value 'baz' into the property 'foo.bar'.
strlist - For <merge> the value is copied to the property and the current property will be overwritten. For <append> and <prepend> the value is append or prepend to the list as new item. For <addset> the strlist is treated as a set and the value is appended if, and only if, the value doesn't exist already. Usage of <copy_property> overwrite the complete list with the value of the given property to copy from.
bool - Can merge the values 'true' or 'false'
int - Merges an integer
uint64 - Merges an unsigned 64-bit integer
double - Merges a double precision floating point number
copy_property - Copies the value of a given property - supports paths with direct and indirect UDI's. For example <merge key="foo.bar" type="copy_property">@info.parent:baz.bat</merge> will merge the value of the property baz.bat on the device object with the UDI from the property info.parent into the property foo.bar on the device object being processed.

The <remove>, directive require only a key and can be used with all keys. For strlist there is additionally a special syntax to remove a item from the string list. For example to remove item 'bla' from property 'foo.bar': <remove key="foo.bar" type="strlist">bla</remove>

Search Paths

Device Information files are read from two directories

/usr/share/hal/fdi - for files provided by packages
/etc/hal/fdi - for files provided by the system administrator / user

in exactly that order. This means that the files provided by the system administrator will be processed last such that they can overwrite / change properties caused by the device information files provided by packages. The following directory structure is used in /usr/share/hal/fdi

information - device information files used to merge device information
- 10freedesktop - included with the hal package
- 20thirdparty - from a 3rd party, not included in hal package
policy - device information files to merge policy properties such as addons or callouts.
- 10osvendor - included with the hal package
- 20thirdparty - from a 3rd party, not included in hal package
preprobe - device information files read before probing devices
- 10osvendor - included with the hal package
- 20thirdparty - from a 3rd party, not included in hal package

As evident, third party packages should drop device information files in

/usr/share/hal/fdi/information/20thirdparty
/usr/share/hal/fdi/policy/20thirdparty
/usr/share/hal/fdi/preprobe/20thirdparty

The /etc/hal/fdi tree uses this layout

information - device information files used to merge device information
policy - device information files to merge policy properties such as addons or callouts.
preprobe - device information files to read before probing devices

All device information files are matched for every hal device object in the following order.

When a device is discovered, the preprobe device information files (e.g. all files from /usr/share/hal/fdi/preprobe and /etc/hal/fdi/preprobe) are processed.
Typically, this class of device information files is used to tell HAL to leave the device alone by setting the bool property info.ignore to TRUE. It can also be used to run programs, preprobe callouts, prior to normal device investigation.
HAL now runs the preprobe callouts.
HAL now probes/investigates the device.
All the information device information files (e.g. all files from /usr/share/hal/fdi/information and /etc/hal/fdi/information) are processed.
These device information files are typically used to associate extra information with a device object.
All the policy policy information files (e.g. all files from /usr/share/hal/fdi/policy and /etc/hal/fdi/policy) are processed.
These device information files are typically used to associate callouts and addons with a device object.
HAL now runs the callouts, starts addons, and then finally announces the device on the system message bus.

Chapter 3. Access Control

Table of Contents

Device Files
D-Bus Interfaces

Access to hardware by unprivileged users is traditionally granted in two ways either by granting access to the special device file or allowing access through another process, using IPC acting on behalf of the user. HAL follows the latter model and uses the system-wide message bus (D-Bus) as the IPC mechanism. In addition, HAL has support for modifying the ACL's (access control lists) on a device file to grant/revoke access to users based on several criteria.

Device Files

If HAL is built with --enable-acl-management (requires both --enable-console-kit and --enable-policy-kit) then ACL's on device objects with the capability access_control are automatically managed according to the properties defined in the section called “ access_control namespace ”. In addition, for this configuration, HAL ships with a device information file (normally installed in /usr/share/hal/fdi/policy/10osvendor/20-acl-management.fdi) that merges this capability on device objects that are normally accessed by unprivileged users through the device file. This includes e.g. sound cards, webcams and other devices but excludes drives and volumes as the latter two are normally accessed by a user through mounting them into the file system.

HAL uses PolicyKit to decide what users should have access according to PolicyKit configuration; see the PolicyKit privilege definition file /etc/PolicyKit/privileges/hal-device-file.priv on a system with HAL installed for the default access suggested by the HAL package and/or OS vendor.

In addition, 3rd party packages can supply device information files to specify (via the access_control.grant_user and access_control.grant_group properties) that a given user or group should always have access to a device file. This is useful for system-wide software (such as AV streaming management) that runs as an unprivileged system user. This interface is supposed to be stable so 3rd party packages can depend on it.

D-Bus Interfaces

If HAL is built without ConsoleKit support (e.g. without --enable-console-kit) access to the various D-Bus interfaces that provides mechanisms is only protected by the D-Bus security configuration files (e.g. using at_console to restrict to console user on Red Hat systems) and, in certain cases, restricted to the super user.

If ConsoleKit support is enabled, access to D-Bus interfaces is currently hardcoded to only allow active users at the system console. If PolicyKit support is enabled, the PolicyKit library will be in charge of determining access; see the PolicyKit privilege definition files in /etc/PolicyKit/privileges on a system with HAL installed for the default access suggested by the HAL package and/or OS vendor.

Chapter 4. Locking

Table of Contents

Overview
Guidelines

As HAL is a mechanism that enables programs in a desktop session to enforce the policy of the users choice, unexpected things can happen. For example, if the user is in the middle of partitioning a disk drive, it is desirable to keep the desktop from mounting partitions that have not yet been prepared with a suitable file system. In fact, in such a situation data loss may be the result if a volume have an old file system signature indicating it's mountable and, simultenously, another tool is writing to the raw block device. The mechanism that automounters use, HAL, provides locking primitives to avoid this.

Further, for multi-user systems, several desktop sessions may run on a system each on their own display. Suppose that one session becomes idle and the power management daemon in that session decides to suspend the system according to user preferences in the idle session. The result is that users at other seats will see the system suspend and this is not desirable. The power management daemons in all sessions need to cooperate to ensure that the system only suspends when e.g. all sessions are idle or not at all. The mechanism that each power management daemon uses, HAL, provides locking primitives that can be used to achieve this.

Overview

HAL provides a mechanism to lock a specific D-Bus interface either for a specific device or for all the devices the caller have access to.

The former is achieved by using the AcquireInterfaceLock() and ReleaseInterfaceLock() methods on the org.freedesktop.Hal.Device interface that every device object implements (see the section called “org.freedesktop.Hal.Device interface”). By using this API, a caller can prevent any other caller from invoking methods on the given interface for the given device object - other callers will simply see the org.freedesktop.Hal.Device.InterfaceLocked exception if they attempt to invoke a method on the given interface on the given device. The locker can specify whether the lock is exclusive meaning if multiple clients clients can hold the lock or if only one client can hold the lock at one time. If a client don't have access to the interface of the device, attempts to lock will fail with a org.freedesktop.Hal.PermissionDenied exception. If a client loses access to a device (say, if his session is switched away from using fast user switching) while holding a lock, he will lose the lock; this can be tracked by listening to the InterfaceLockReleased signal.

All local clients, whether they are active or not, can always lock interfaces on the root computer device object (this doesn't mean that they are privileged to use the interfaces though) - the rationale is that this device object represents shared infrastructure, e.g. power management, and even inactive sessions needs to participate in managing this.

If another client already holds a lock exclusively, attempts from other clients to acquire the lock will fail with the org.freedesktop.Hal.Device.InterfaceAlreadyLocked exception even if they have access to the device.

In addition, a client may opt to lock all devices that he got access to by using the AcquireGlobalInterfaceLock() and ReleaseGlobalInterfaceLock() methods on the org.freedesktop.Hal.Manager interface on the /org/freedesktop/Hal/Manager object (see the section called “org.freedesktop.Hal.Manager interface”). Global interface locks can also be obtained exclusively if the caller so desires. Unlike per-device interface locking, it is not checked at locking time whether the locker have access to a given device; instead checking is done when callers attempt to access the interface.

The algorithm used for determining if a caller is locked out is shown below. A caller A is locked out of an interface IFACE on a device object DEVICE if, and only if,

Another caller B is holding a lock on the interface IFACE on DEVICE and A don't have either a global lock on IFACE or a lock on IFACE on DEVICE; or
Another caller B is holding the global lock on the interface IFACE and B has access to DEVICE and and A don't have either a global lock on IFACE or a lock on IFACE on DEVICE.

In other words, a caller A can grab a global lock, but that doesn't mean A can lock other clients out of devices that A doesn't have access to. Specifically a caller is never locked out if he has locked an interface either globally or on the device in question. However, if two clients have a lock on a device, then both can access it. To ensure that everyone is locked out, a caller needs to use an exclusive lock.

Note that certain interfaces will also check whether other locks are being held on other device objects. This is specified on a per-interface basis in Chapter 6, D-Bus interfaces.

If a process holding locks disconnects from the system bus, the locks being held by that process will be released.

Guidelines

Locking is only useful if applications requiring exclusive access actually use the locking primitives to cooperate with other applications. Here is a list of guidelines.

Disk Management / Partitioning
In order to prevent HAL-based automounters from mounting partitions that are being prepared, applications that access block devices directly (and pokes the kernel to reload the partitioning table) should lock out automounters by either a) obtaining the org.freedesktop.Hal.Device.Storage lock on each drive being processed; or b) obtaintaing the global org.freedesktop.Hal.Device.Storage lock. This includes programs like fdisk, gparted, parted and operating system installers. See also the section called “org.freedesktop.Hal.Device.Volume interface” and the hal-lock(1) program and manual page.
Power Management
Typically, a desktop session includes a session-wide power management daemon that enforces the policy of the users choice, e.g. whether the system should suspend to ram on lid close, whether to hibernate the system after the user being idle for 30 minutes and so on. In a multi-user setup (both fast user switching and multi-seat), this can break in various interesting ways unless the power management daemons cooperate. Also, there may be software running at the system level who will want to inhibit a desktop session power management daemon from suspending / shutting down.
- System-level software that do not wish to be interrupted by the effect of someone calling into the org.freedesktop.Hal.Device.SystemPowerManagement interface MUST hold the org.freedesktop.Hal.Device.SystemPowerManagement lock non-exclusively on the root computer device object. For example, the YUM software updater should hold the lock when doing an RPM transaction.
In addition, any power management session daemon instance
- ... MUST hold the org.freedesktop.Hal.Device.SystemPowerManagement lock non-exclusively on the root computer device object unless it is prepared to call into this interface itself. This typically means that the PM daemon instance simply acquires the lock on start up and releases it just before it calls into the org.freedesktop.Hal.Device.SystemPowerManagement interface. In other words, the PM daemon instance needs to hold the lock exactly when it doesn't want other PM daemon instances to call into the org.freedesktop.Hal.Device.SystemPowerManagement interface. This means that if the user have configured the PM daemon instance to go to sleep after 30 minutes of inactivity, the lock should be released then.
- ... MUST not hold the lock when the session is inactive (fast user switching) UNLESS an application in the session have explicitly called Inhibit() on the org.freedesktop.PowerManagement D-Bus session bus interface of the PM daemon.
- ... MUST check that no other process is holding the lock (using the IsLockedByOthers method on the standard org.freedesktop.Hal.Device interface) before calling into the org.freedesktop.Hal.Device.SystemPowerManagement interface. If another process is holding the lock, it means that either 1) another session is not prepared to call into the org.freedesktop.Hal.Device.SystemPowerManagement interface; OR 2) some system-level software is holding the lock. The PM daemon instance MUST respect this by not calling into the org.freedesktop.Hal.Device.SystemPowerManagement interface itself.
However, any Power management daemon instance
- ... MAY prompt the user, if applicable, to ask if she still wants to perform the requested action (e.g. call into the org.freedesktop.Hal.Device.SystemPowerManagement interface) despite the fact that another process (possibly from another user) is indicating that it does not want the system to e.g. suspend. Only if the user agrees, the power management instance should call into the org.freedesktop.Hal.Device.SystemPowerManagement interface. Typically, it's only useful to prompt the user with such questions if the request to call into the org.freedesktop.Hal.Device.SystemPowerManagement interface originates from user input, e.g. either a hotkey, the user clicking a suspend button in the UI or an application invoking the Suspend() method on the org.freedesktop.PowerManagement D-Bus session interface of the PM daemon.
- ... MAY ignore that other processes are holding the lock and call into the org.freedesktop.Hal.Device.SystemPowerManagement interface anyway, but ONLY if if the request to call into the org.freedesktop.Hal.Device.SystemPowerManagement interface originated from e.g. lid close, critically low battery or other similar conditions.
- ... MAY still call SetPowerSave() on the org.freedesktop.Hal.Device.SystemPowerManagement interface even if other processes are holding the lock.

Chapter 5. Device Properties

Table of Contents

General Properties

info namespace
Callouts
Addons
Method calls

Subsystem-Specific Properties

pci namespace
serial namespace
usb_device namespace
usb namespace
platform namespace
ide_host namespace
ide namespace
scsi_host namespace
scsi namespace
ieee1394_host namespace
ieee1394_node namespace
ieee1394 namespace
mmc_host namespace
mmc namespace
ccw namespace
ccwgroup namespace
iucv namespace
block namespace
xen namespace
bluetooth_hci namespace
bluetooth_acl namespace
bluetooth_sco namespace

Functional Properties

system namespace
volume namespace
volume.disc namespace
storage namespace
storage.cdrom namespace
storage.linux_raid namespace
net namespace
net.80203 namespace
net.80211 namespace
net.bluetooth namespace
net.irda namespace
net.80211control namespace
input namespace
input.keys namespace
input.keypad namespace
input.keyboard namespace
input.mouse namespace
input.switch namespace
input.joystick namespace
input.tablet namespace
input.keymap namespace
pcmcia_socket namespace
printer namespace
portable_audio_player namespace
alsa namespace
oss namespace
camera namespace
scanner namespace
laptop_panel namespace
ac_adapter namespace
battery namespace
button namespace
processor namespace
light_sensor namespace
power_management namespace
tape namespace
killswitch namespace

Misc. Properties

access_control namespace

Deprecated Properties

Properties are arranged in a namespaces using ''.'' as a separator and are key/value pairs. The value may assume different types; currently int32, double, bool, UTF8 strings and UTF8 string lists are supported. The key of a property is always an ASCII string without any whitespace. When a property changes, HAL will emit a D-Bus signal that applications can catch.

General Properties

The section represents properties that aren't tied to either physical or functional characteristics of what the device object represents.

info namespace

The info namespace contain properties that can be considered metadata about device objects. These properties are always available.

Key (type)	Values	Mandatory	Description
`info.subsystem` (string)	pci, usb, ide_host, ide, block, usb, usbif, scsi_host, scsi	Yes	Describes what subsystem the device is connected to
`info.udi` (string)	example: /org/freedesktop/Hal/devices/pci_10ec_8139	Yes	The HAL unique device id
`info.capabilities` (strlist)	example: 'block, storage, storage.cdrom'	No	A string list of capabilities describing what the devices does
`info.category` (string)	example: storage.cdrom	No	The prominent capability describing what the device is
`info.product` (string)	examples: ''SleekKeyboard'', ''MouseMan 2003'', ''Volume'', ''LS-120 SLIM3 00 UHD Floppy''	No	The name of the device; should not be used in any UI; use subsystem / capability specific properties instead.
`info.vendor` (string)	examples: Logitch, Mustek	No	The name of the vendor of the device; should not be used in any UI; use subsystem / capability specific properties instead.
`info.parent` (string)	example: /org/freedesktop/Hal/devices/computer	Yes, for all non-root device objects	The UDI of the device object that this device object is connected to.
`info.locked` (bool)		No	If this property is available and set to `TRUE` it means that a process is using the device that the hal device object in question represents and no other process should attempt to use or configure the device. The lock is only advisory.
`info.locked.reason` (string)	example: ''The optical drive is currently being used to record a CD-RW disc.''	Only available if `info.locked` is set to `TRUE`.	A localized text suitable for UI display
`info.locked.dbus_service` (string)	example: :1.278	Only available if `info.locked` is set to `TRUE`.	The base D-BUS service of the process holding the lock.
`info.is_recalled` (bool)		No	This is set if the hardware may be recalled and should be checked for any potential problem.
`info.recall.vendor` (string)	Dell, Sony, HP, Panasonic, etc.	Yes, if `info.is_recalled` is TRUE	The vendor responsible for the hardware recall.
`info.recall.website_url` (string)		Yes, if `info.is_recalled` is TRUE	Users should check this website for more details and if their hardware may affected by any possible fault.

Callouts

Callouts are programs invoked when the device object are added and removed. As such, callouts can be used to maintain system-wide policy (that may be specific to the particular OS) such as changing permissions on device nodes, updating the systemwide /etc/fstab file or configuring the networking subsystem.

There are three different classes of callouts. A callout involves sequentially invoking all executable programs in the string list in listed order.

All callouts are searched for and execute in a minimal environment. In addition, the UDI of the device object is exported in the environment variable UDI. All properties of the device object are exported in the environment prefixed with HAL_PROP_. If a device is added or removed is exported in the environment variable HALD_ACTION. The search path for the callout includes the following paths:

$libexecdir (typically /usr/libexec (e.g. Red Hat) or /usr/lib/hal (e.g. Debian))
$libdir/hal/scripts (typically /usr/lib/hal/scripts or /usr/lib64/hal/scripts)
$bindir/ (typically /usr/bin)

including $PATH the HAL daemon was started with during system initialization. Depending on the distribution, this typically includes /sbin, /usr/sbin, /bin, /usr/sbin. If the program to run is not found in any of these paths, the it will not run even if the given path is absolute. To be portable across operating systems, third party packages providing callouts must therefore only use $libdir/hal/scripts.

If ConsoleKit support is enabled, the variables CK_NUM_SEATS (number of seats), CK_NUM_SESSIONS (number of sessions), CK_SEATS (tab sep. list of seat-id's), CK_SEAT_seat-id (tab sep. list of session-id's for a seat), CK_SEAT_NUM_SESSIONS_seat-id (number of sessions on a seat), CK_SESSION_SEAT_session-id (the seat that a session belongs to) and CK_SESSION_IS_ACTIVE_session-id (whether a given session is active) and CK_SESSION_UID_session-id (the user of the session) and CK_SESSION_IS_LOCAL_session-id (whether a session is local), CK_SESSION_HOSTNAME_session-id (host name of session's display if it's not local), will be exported as well. Example:

CK_NUM_SEATS=1
CK_NUM_SESSIONS=2
CK_SEATS=Seat1
CK_SEAT_Seat1=Session1  Session3
CK_SEAT_NUM_SESSIONS_Seat1=2
CK_SESSION_IS_ACTIVE_Session1=true
CK_SESSION_IS_ACTIVE_Session3=false
CK_SESSION_IS_LOCAL_Session1=true
CK_SESSION_IS_LOCAL_Session3=true
CK_SESSION_SEAT_Session1=Seat1
CK_SESSION_SEAT_Session3=Seat1
CK_SESSION_UID_Session1=500
CK_SESSION_UID_Session3=501

Note that all ConsoleKit object paths given are just base names; the real D-Bus object path can be reconstructed by appending /org/freedesktop/ConsoleKit/ prepended to the given identifer.

The HAL daemon is not suspended while callouts are executing. Thus, callouts can communicate with the HAL daemon using the D-BUS network API. Hence, one application of callouts is to merge or modify properties on a device object.

To reduce round trips and increase privacy, callouts can (and should) communicate with the HAL daemon using a peer to peer D-Bus connection specified by the HALD_DIRECT_ADDR environment variable. There is convience API in libhal to do this.

Key (type)	Mandatory	Description
`info.callouts.add` (string list)	No	A string list with the programs which should be executed (with `HALD_ACTION=add`) when the device is added to the GDL (global device list) but just before it is announced through the D-BUS network API.
`info.callouts.remove` (string list)	No	A string list with the programs that should be executed (with `HALD_ACTION=remove`) when the device is removed from the GDL (global device list). The device isn't removed before the last callout has finished.
`info.callouts.preprobe` (string list)	No	A string list with the programs that should be executed (with `HALD_ACTION=preprobe`) before the device is probed (e.g. investigated) and can be used to avoid causing unnecessary I/O.
`info.callouts.session_add` (string list)	No	A string list with all programs that should be executed (with `HALD_ACTION=session_add`) when a session is added. Can only be set on the root computer device object. The environment also contains the variables `HALD_SESSION_ADD_SESSION_ID`, `HALD_SESSION_ADD_SESSION_UID` and `HALD_SESSION_ADD_SESSION_IS_ACTIVE` to identify the session. This is only used when HAL is built with ConsoleKit support.
`info.callouts.session_remove` (string list)	No	A string list with all programs which should be executed (with `HALD_ACTION=session_remove`) when a session is removed. Can only be set on the root computer device object. The environment also contains the variables `HALD_SESSION_REMOVE_SESSION_ID`, `HALD_SESSION_REMOVE_SESSION_UID` and `HALD_SESSION_REMOVE_SESSION_IS_ACTIVE` to identify the session. This is only used when HAL is built with ConsoleKit support.

Addons

Addons are programs that run for the life time of the device object. They are searched for and execute in the same environment as callouts (e.g. with HAL_PROP_* set in the environment to represent the device properties) and are launched just before the device is announced on D-Bus (but just after the last add callouts have finished). When the device object goes away, HAL will send a SIGTERM to the process.

Key (type)	Values	Mandatory	Description
`info.addons` (strlist)		No	List of programs to run when device is added. Each program will need to call the `AddonIsReady()` method in order for the device to show up on D-Bus.

Method calls

Method calls on a specific interface on a device object can be implemented by the HAL daemon running a program. Note that this is not the only way to implement support for method calls; if you expect a lot of method calls it is preferable to implement an addon and use the ClaimInterface() API since it reduces the overhead of spawning a process and it can handle both complex incoming and return types as well. See the section called “org.freedesktop.Hal.Device interface” for details on claiming interfaces via an addon..

Note that method calls implemented via running a program are limited to the return type being an unsigned 32-bit integer (this will change in a future release so it's configurable per method). The incoming parameters are limited to only basic types and arrays of strings. The parameters are passed via stdin using a textual representation. As such, there is a lot of overhead with handling method calls by spawning programs and as such it should only be used for situtations where the nature of the method call is that it will not be frequently used.

As with addons, method calls are searched for and execute in the same minimal environment as callouts (e.g. with HAL_PROP_* set in the environment to represent the device properties) and in addition the environment variables HAL_METHOD_INVOKED_BY_UID (the uid of the caller) and HAL_METHOD_INVOKED_BY_SYSTEMBUS_CONNECTION_NAME (the unique system bus connection name of the caller) are set. Additionally, if HAL is built with ConsoleKit support, HAL_METHOD_INVOKED_BY_PID and HAL_METHOD_INVOKED_BY_SELINUX_CONTEXT (but only if the running system have SELinux enabled) will be set. If HAL itself, or a HAL addon, is invoking a method, then these variables will not be present. Here's an example

HAL_METHOD_INVOKED_BY_UID=500
HAL_METHOD_INVOKED_BY_PID=22553
HAL_METHOD_INVOKED_BY_SELINUX_CONTEXT=user_u:system_r:unconfined_t
HAL_METHOD_INVOKED_BY_SYSTEMBUS_CONNECTION_NAME=:1.138

In addition, with ConsoleKit support, HAL_METHOD_INVOKED_BY_SESSION will be set to (the basename) of the ConsoleKit session object path but only if the caller is in a session. The method handler can then use the previously mentioned CK_SESSION_* to learn everything about the context of the caller.

Key (type)	Values	Mandatory	Description
`info.interfaces` (strlist)		No	A list of D-Bus interfaces that the device object supports apart from the standard `org.freedesktop.Hal.Device` interface.
`<iface>.method_names` (strlist)	example: `'Foo', 'Bar', 'Baz'`	No	If a D-Bus interface is implemented by executing a program for every method, this property contains an ordered list of the method names.
`<iface>.method_argnames` (strlist)	example: `'foo_arg1 foo_arg2', '', 'baz_arg1'`	No	This property contains the names of the arguments for each method. Each entry is a white-space separated list for that particular method.
`<iface>.method_signatures` (strlist)	example: `'si', '', 'as'`	No	This property contains the D-Bus signature for each method. The signature should only cover incoming arguments; each method is defined as returning an integer.
`<iface>.method_execpaths` (strlist)	example: `'foo-binary', 'bar-binary', 'baz-binary'`	No	This property contains the name of the program to execute when this method is called. The return code of the program will be passed as the integer result to the D-Bus caller. If a program wants to return an error, it just needs to write two lines to stderr; the first line is the exception name to throw and the second line is the exception detail.

Items in the <iface>.* clearly must correspond with each other. The whole mechanism is best explained by an example:

info.interfaces = {'org.freedesktop.Hal.Device.Volume'}
org.freedesktop.Hal.Device.Volume.method_argnames = {'mount_point fstype extra_options', 'extra_options', 'extra_options'}
org.freedesktop.Hal.Device.Volume.method_execpaths = {'hal-storage-mount', 'hal-storage-unmount', 'hal-storage-eject'}
org.freedesktop.Hal.Device.Volume.method_names = {'Mount', 'Unmount', 'Eject'}
org.freedesktop.Hal.Device.Volume.method_signatures = {'ssas', 'as', 'as'}

which, for example, shows that the Mount() method on the interface org.freedesktop.Hal.Device.Volume takes three arguments: mount_point (a string), fstype (a string) and extra_options (an array of strings).

Subsystem-Specific Properties

In this section properties for device objects that represent addressable hardware is described. Availability of these depends on the value of the info.subsystem property. These properties are not of particular interest to application developers, instead they are useful for libraries and userspace drivers that needs to interact with the device given a UDI. Knowledge of various subsystem-specific technologies is assumed for this section to be useful.

pci namespace

This namespace contains properties for device objects representing functions on devices on a PCI bus. These properties are available exactly when info.subsystem equals pci.

Key (type)	Values	Mandatory	Description
`pci.device_class` (int)	example: 3	Yes	Device Class
`pci.device_subclass` (int)	example: 0	Yes	PCI Device Sub Class
`pci.device_protocol` (int)	example: 0	Yes	Device Protocol
`pci.product_id` (int)	example: 0x4c4d	Yes	Product ID
`pci.vendor_id` (int)	example: 0x1002	Yes	Vendor ID
`pci.subsys_product_id` (int)	example: 0x009e	Yes	Subsystem product id
`pci.subsys_vendor_id` (int)	example: 0x1028	Yes	Subsystem vendor id
`pci.linux.sysfs_path` (string)	example: /sys/devices/pci0000:00/0000:00:01/0000:01:00.0	Yes (only on Linux)	Equals `linux.sysfs_path`
`pci.product` (string)	Rage Mobility P/M AGP 2x	No	Name of the product per the PCI database
`pci.vendor` (string)	ATI Technologies Inc	No	Name of the vendor per the PCI database
`pci.subsys_product` (string)	Inspiron 7500	No	Name of the subsystem product per the PCI database
`pci.subsys_vendor` (string)	Dell Computer Corporation	No	Name of the subsystem vendor per the PCI database

(FIXME: Some key PCI information (bus, slot, port, function etc.) is missing here)

serial namespace

Device objects that represent serial devices (e.g. /dev/ttyS* or /dev/ttyUSB*).

Key (type)	Values	Mandatory	Description
`serial.originating_device` (string)	example: `/org/freedesktop/Hal/devices/pnp_PNP0501`	Yes	UDI of the device the serial device is bound to.
`serial.device` (string)	example: /dev/ttyS0	Yes	The device node to access the OSS device.
`serial.port` (int)	example: 0	Yes	The port number of the device, based on the number in `serial.device`
`serial.type` (string)	example: platform, usb, unknown	Yes	This property defines the type of the serial device.

usb_device namespace

For device objects representing USB devices the property info.subsystem will be usb_device, and the following properties will be available. Note that the corresponding USB interfaces are represented by separate device objects as children.

Key (type)	Values	Mandatory	Description
`usb_device.bus_number` (int)	example: 1	Yes	The USB bus the device is attached to
`usb_device.configuration_value` (int)	example: 1	Yes	The current configuration the USB device is in; starting from 1
`usb_device.configuration` (int)	example: Bulk transfer configuration	No	Human-readable description of the current configuration the USB device is in
`usb_device.num_configurations` (int)	example: 1	Yes	Number of configurations this USB device can assume
`usb_device.device_class` (int)	example: 0	Yes	USB Device Class
`usb_device.device_subclass` (int)	example: 0	Yes	USB Device Sub Class
`usb_device.device_protocol` (int)	example: 0	Yes	USB Device Protocol
`usb_device.is_self_powered` (bool)	example: false	Yes	The device, in the current configuration, is self powered
`usb_device.can_wake_up` (bool)	example: true	Yes	The device, in the current configuration, can wake up
`usb_device.max_power` (int)	example: 98	Yes	Max power drain of device, in mA
`usb_device.num_interfaces` (int)	example: 1	Yes	Number of USB Interfaces in the current configuration
`usb_device.num_ports` (int)	example: 0	Yes	Number of ports on a hub. Zero for non-hubs
`usb_device.port_number` (int)	example: 1	Yes	The port number on the parent hub that the device is attached to, starting from 1
`usb_device.speed` (double)	examples: 1.5, 12.0, 480.0	Yes	Speed of device, in Mbit/s
`usb_device.version` (double)	examples: 1.0, 1.1, 2.0	Yes	USB version of device
`usb_device.level_number` (int)	example: 2	Yes	Depth in USB tree, where the virtual root hub is at depth 0
`usb_device.linux.device_number` (string)	example: 19	Yes (only on Linux)	USB Device Number as assigned by the Linux kernel
`usb_device.linux.parent_number` (string)	example: 19	Yes (only on Linux)	Device number of parent device as assigned by the Linux kernel
`usb_device.linux.sysfs_path` (string)	example: /sys/devices/pci0000:00/0000:00:07.2/usb1/1-1/1-1.1	Yes (only on Linux)	Equals `linux.sysfs_path`
`usb_device.product_id` (int)	example: 0x3005	Yes	USB Product ID
`usb_device.vendor_id` (int)	example: 0x04b3	Yes	USB Vendor ID
`usb_device.device_revision_bcd` (int)	example: 0x0100	Yes	Device Revision Number encoded in BCD with two decimals
`usb_device.serial` (string)		No	A string uniquely identifying the instance of the device; ie. it will be different for two devices of the same type. Note that the serial number is broken on some USB devices.
`usb_device.product` (string)	example: IBM USB HUB KEYBOARD	No	Name of the product per the USB ID Database
`usb_device.vendor` (string)	example: IBM Corp.	No	Name of the vendor per the USB ID Database

usb namespace

Device objects that represent USB interfaces, ie. when info.subsystem assumes usb, are represented by the properties below. In addition all the usb_device.* properties from the parent USB device is available in this namespace but only with the usb prefix instead of usb_device.

Key (type)	Values	Mandatory	Description
`usb.interface.class` (int)	example: 0x03	Yes	USB Class for the interface
`usb.interface.subclass` (int)	example: 0x01	Yes	USB Sub Class for this interface
`usb.interface.protocol` (int)	example: 0x01	Yes	USB Protocol for the interface
`usb.interface.description` (int)	example: SyncML interface	No	Human-readable description for the interface provided by the device
`usb.interface.number` (int)	example: 1	Yes	Number of this interface, starting from zero
`usb.linux.sysfs_path` (string)	example: /sys/devices/pci0000:00/0000:00:07.2/usb1/1-1/1-1.1/1-1.1:1.0	Yes (only on Linux)	Equals `linux.sysfs_path`

platform namespace

Devices that are built into the platform or present on busses that cannot be properly enumerated (e.g. ISA) are represented by device objects where info.subsystem equals platform. These kind of devices are commonly, somewhat incorrectly, called legacy devices.

Key (type)	Values	Mandatory	Description
`platform.id` (string)	example: serial	Yes	Device identification

ide_host namespace

The ide_host namespace is present for device objects where info.subsystem is set to ide_host. Such device objects represent IDE and ATA host adaptors for harddisks and optical drives as found in the majority of computer systems.

Key (type)	Values	Mandatory	Description
`ide_host.number` (int)		Yes	A unique number identifying the IDE host adaptor
`ide_host.linux.sysfs_path` (string)	example: /sys/devices/pci0000:00/0000:00:07.1/ide0	Yes (only on Linux)	Equals `linux.sysfs_path`

ide namespace

ATA and IDE drives are represented by device objects where info.subsystem equals ide. The following properties are available for such device objects.

Key (type)	Values	Mandatory	Description
`ide.host` (int)		Yes	Corresponds to `ide_host.host_number` of the `ide_host` device that is the parent of this device object
`ide.channel` (int)		Yes	Identifies the IDE channel of the host interface

scsi_host namespace

The scsi_host namespace is present for device objects where info.subsystem is set to scsi_host. Such device objects represent SCSI host adaptors for SCSI devices as found in some computer systems.

Key (type)	Values	Mandatory	Description
`scsi_host.host` (int)		Yes	A unique number identifying the SCSI host adaptor

scsi namespace

SCSI devices are represented by device objects where info.subsystem equals scsi. The following properties are available for such device objects.

Key (type)	Values	Mandatory	Description
`scsi.host` (int)		Yes	Corresponds to `scsi_host.host` of the `scsi_host` device that is the parent of this device object
`scsi.bus` (int)		Yes	SCSI channel number
`scsi.target` (int)		Yes	SCSI identifier number
`scsi.lun` (int)		Yes	SCSI Logical Unit Number
`scsi.type` (string)	Example: disk	Yes	SCSI device type
	cdrom		This is a SCSI cdrom device.
	comm		This is a SCSI communication device.
	disk		This is a SCSI disk device.
	medium_changer		This is a SCSI media changer (e.g. for CD/Tape).
	printer		This is a SCSI printer.
	processor		This is a SCSI processor device.
	raid		This is a SCSI raid device.
	scanner		This is a SCSI scanner.
	tape		This is a SCSI tape device.
	unknown		The type of this SCSI device is unknwon.

ieee1394_host namespace

Device objects with info.subsystem set to ieee1394_host represent IEEE 1394 host adaptors. The following properties are available for such device objects.

Key (type)	Mandatory	Description
`ieee1394_host.is_busmgr` (bool)	Yes	TODO
`ieee1394_host.is_irn` (bool)	Yes	TODO
`ieee1394_host.is_root` (bool)	Yes	TODO
`ieee1394_host.node_count` (int)	Yes	TODO
`ieee1394_host.nodes_active` (int)	Yes	TODO

ieee1394_node namespace

Device objects with info.subsystem set to ieee1394_node represent IEEE 1394 nodes on a IEEE 1394 bus. The following properties are available for such device objects.

Key (type)	Mandatory	Description
`ieee1394_node.capabilities` (int)	Yes	TODO
`ieee1394_node.guid` (int)	Yes	TODO
`ieee1394_node.nodeid` (int)	Yes	TODO
`ieee1394_node.vendor` (int)	Yes	TODO
`ieee1394_node.vendor_id` (int)	Yes	TODO

ieee1394 namespace

Device objects with info.subsystem set to ieee1394 represent IEEE 1394 devices. The following properties are available for such device objects.

Key (type)	Values	Mandatory	Description
`ieee1394.specifier_id` (int)		Yes	TODO

mmc_host namespace

Device objects with info.subsystem set to mmc_host represent MultiMediaCard or Secure Digital host adaptors. The following properties are available for such device objects.

Key (type)	Values	Mandatory	Description
`mmc_host.host` (int)		Yes	A unique number identifying the MMC/SD host adaptor

mmc namespace

Device objects with info.subsystem set to mmc represent MultiMediaCard or Secure Digital cards. The following properties are available for such device objects.

Key (type)	Values	Mandatory	Description
`mmc.cid` (string)	example: 0150415330303842413a1a8083003a9d	Yes	Card Identification Data register (unique for every card in existence)
`mmc.csd` (string)	example: 005d013213598067b6d9cfff1640002d	Yes	Card Specific Data register
`mmc.scr` (string)	example: 00a5000000410000	Only for SD cards	SD Card Register
`mmc.rca` (int)	example: 8083	Yes	Card bus address
`mmc.oem` (string)		Yes	Card OEM distributor
`mmc.date` (string)	example: 10/2003	Yes	Manufacturing date
`mmc.serial` (int)	example: 0x3a1a8083	Yes	Card serial number
`mmc.hwrev` (int)	example: 4	Yes	Hardware revision
`mmc.fwrev` (int)	example: 1	Yes	Firmware revision

ccw namespace

Device objects that represent s390 ccw devices (when info.subsystem is set to ccw) are represented by the properties below.

Key (type)	Values	Mandatory	Description
`ccw.devtype` (string)	example: 1732/01	Yes	Device type/model or n/a
`ccw.cutype` (string)	example: 1731/01	Yes	Control unit type/model
`ccw.cmb_enable` (int)	example: 1	Yes	If channel measurements are enabled
`ccw.availability` (string)	example: good	Yes	Can be one of 'good', 'boxed', 'no path', or 'no device'
`ccw.online` (int)	example: 1	Yes	Online status
`ccw.bus_id` (string)	example: 0.0.f588	Yes	The device's bus id in sysfs
`ccw.subchannel.pim` (int)	example: 0x80	No	path installed mask
`ccw.subchannel.pam` (int)	example: 0x80	No	path available mask
`ccw.subchannel.pom` (int)	example: 0xff	No	path operational mask
`ccw.subchannel.chpid0..7` (int)	example: 0x40	No	channel path ids

The following properties describe ccw devices where linux.driver is either dasd-eckd or dasd-fba.

Key (type)	Values	Mandatory	Description
`ccw.dasd.use_diag` (int)	example: 0	Yes	If the device driver shall use diagnose calls to access the device
`ccw.dasd.readonly` (int)	example: 0	Yes	If the device can only be accessed readonly
`ccw.dasd.discipline` (string)	example: ECKD	No	The dasd discipline used to access the device

The following properties describe ccw devices where linux.driver is zfcp. They are only present when ccw.online = 1.

Key (type)	Values	Mandatory	Description
`ccw.zfcp.in_recovery` (int)	example: 0	Yes	Shows whether the adapter is currently in recovery
`ccw.zfcp.failed` (int)	example: 0	Yes	Shows whether the adapter is in failed state

The following properties describe ccw devices where linux.driver is of the form tape_3xxx .

Key (type)	Values	Mandatory	Description
`ccw.tape.state` (string)	example: IN_USE	Yes	The current status of the tape
`ccw.tape.operation` (string)	example: REW	Yes	A three-letter mnemonic of the current tape operation
`ccw.tape.medium_state` (string)	example: no medium	No	If `ccw.online = 1`, shows whether a tape is loaded
`ccw.tape.blocksize` (int)	example: 512	No	If `ccw.online = 1`, shows the blocksize used for reads and writes to the tape

The following properties describe ccw devices where linux.driver is 3270.

Key (type)	Values	Mandatory	Description
`ccw.3270.model` (int)	example: 3	Yes	The model of the device, determining rows and columns
`ccw.3270.rows` (int)	example: 32	Yes	The number of rows
`ccw.3270.columns` (int)	example: 80	Yes	The number of columns

ccwgroup namespace

Device objects that represent groups of ccw devices (when info.subsystem is set to ccwgroup have the properties specified below.

Key (type)	Values	Mandatory	Description
`ccwgroup.online` (int)	example: 1	Yes	Online status
`ccwgroup.bus_id` (string)